KR20160042452A - Valve - Google Patents

Abstract

The valve comprises: a housing 101 surrounding the fluid outlet 102; a valve element 103 having a longitudinal axis 104; and a sealing sheet 107 surrounding the fluid inlet 106, (100) is closed when the valve element (103) supports the sealing sheet (107), and the valve element (103) is connected to the fluid Is movable in the direction of the longitudinal axis (104) with respect to the valve seat body (105) for fluid flow from the inlet (106) to the fluid outlet (102), the valve seat body (105) The valve seat 103 surrounds the guide surface 108 to which the valve element 103 is coupled to guide the movement of the valve seat body 103 and the valve seat body 105 is formed of a material that is harder than the housing 101.

Description

Valve {VALVE}

The present invention relates to a valve, and more particularly, to a valve for a fuel injection system for an internal combustion engine of an automobile.

In a fuel injection system, the valve is subjected to a strong load when exposed to a pressure of, for example, 2000 bar or more. When the valve comprises an electromagnetic actuator, it is often made of a relatively soft material for magnetic reasons. The soft material is protected from high pressure and wear by additional components.

It is sought to present a valve which can operate reliably and which can be manufactured particularly cheaply.

In one embodiment of the invention, the valve includes a housing surrounding the fluid outlet. The valve includes a valve element having a longitudinal axis. The valve further comprises a valve seat body. The valve seat body surrounds the fluid inlet and has a sealing seat to act to close the valve when the valve element bear the sealing sheet. The valve seat body is coupled to the housing. The valve element is longitudinally axially movable relative to the valve seat body to permit fluid flow from the fluid inlet to the fluid outlet. The valve seat body surrounds the guide surface to which the valve element is coupled to guide the valve element. The valve seat body is formed of a material that is harder than the housing.

The valve may be used as a valve, particularly in a fuel injection system of an internal combustion engine. The valve is used, for example, as a pressure-limiting valve. The valve may remain closed to a predetermined predefined pressure and may open when the pressure is exceeded such that fluid may flow from the fluid inlet through the valve seat body to the fluid outlet. From there, the fluid flow returns, for example, in the direction of the fluid tank.

For example, the valve element in the form of a pin or valve needle is particularly coupled to an electromagnetic actuator. The electromagnetic actuator is designed to move the valve element with respect to the valve seat body along the longitudinal axis so that the valve element moves in a direction away from the sealing sheet. The electromagnetic actuating member is coupled to the housing. The housing is particularly formed from a relatively soft material so that the electromagnetic actuator can operate reliably. The housing guides fluid at the low pressure side. The housing does not guide fluid filled at high pressures above 2000 bar.

The valve seat body is formed of a material that is harder than the housing. The valve seat body surrounds a fluid inlet capable of guiding the fluid to a pressure of at least 2000 bar. The valve seat body contacts the valve element and guides the valve element. Thus, the valve element is guided by the valve seat body formed of the relatively rigid material. In particular, the material of the housing has a lower hardness than the valve seat body. The valve element is guided in the rigid material, thereby preventing wear of the guide. In this way, the accuracy and reliability of the valve is also increased when operating for a relatively long period of time. Furthermore, the sealing sheet and the guide are formed on the same valve seat body, resulting in a smaller tolerance. In this way, manufacturing precision is increased because the elements that need to be attached to precise positions are integrated and arranged on a common axis.

Rigid materials are understood to mean particularly hard-to-mechanically rigid materials, i.e. materials that are more difficult to deform than relatively soft materials. Ductile materials include materials that are particularly magnetically soft.

The relatively hard material may be, for example, a martensitic steel including, in particular, the following elements: Cr, C, Mn, Si, P, S and Mo. In this case, the composition of the material is in particular 16-18% Cr, 0.6-1.2% C, 1% Mn, 1% Si, 0.04% P, 0.03% Mo. ≪ / RTI > The relatively hard material may be, for example, steel having SAE designation 440. The relatively hard steel has a Rockwell hardness of C50 to C70, in particular C55 to C66, including for example a Rockwell hardness of at least C50, for example an extremum.

The relatively soft material is preferably a magentic material. The relatively hard material may be a non-magnetic material.

In particular, the relatively soft material may be ferritic steel, which in particular comprises the following elements: Cr, C, Mn, Si, P and S and additionally Ni or Mo. In this case, the composition of the material is in particular 16-18% Cr, 0.75% Ni, 0.12% C, 1% Mn, 1% Si, 0.04% P and 0.03% Lt; / RTI > The relatively soft material may be, for example, steel having the SAE standard 430. The relatively soft steel may have a Rockwell hardness of B70 to B100, in particular B80 to B90, including, for example, a Rockwell hardness of B100 or less, e.g., the extremum.

In a further embodiment, the coupling between the guide surface and the valve element allows fluid to flow along the valve element and guide surface. No sealing action is shown for guiding the valve element in the valve seat body.

In an embodiment, the valve element has a recess for fluid flow from the fluid inlet to the fluid outlet at least in the region of the guide surface when viewed along the longitudinal axis. By virtue of the recesses, when the valve is open, fluid can be guided along the longitudinal axis through the guide section at the guide surface. The recess extends particularly beyond the sealing sheet body in a direction away from the sealing sheet. In this way, the fluid can be reliably and rapidly discharged to the fluid outlet.

In a further embodiment, the valve seat body has a fluid line oriented transversely with respect to the longitudinal axis for fluid flow from the fluid inlet to the fluid outlet. When the valve is open, the fluid may pass from the fluid inlet to the fluid outlet through the fluid line. In an embodiment, the valve includes a recess in the valve element or a fluid line in the valve seat body, but not both. In a further embodiment, the valve may include a recess in the valve element and the fluid line in the valve seat body.

In a further embodiment, the valve seat body has a fluid chamber in the sealing sheet having a wall. The liquid jets reach the wall when fluid flow from the fluid inlet to the fluid outlet is allowed. When the valve is opened, a strong liquid jet is generated from the high pressure side to the low pressure side. The jet reaches the wall of the valve seat body, which is made of the relatively rigid material. The valve seat body is less worn than the relatively soft material. Further, additional components to be protected from the liquid jet can be eliminated. Therefore, it can be manufactured simply and inexpensively, and can operate reliably with almost no wear.

Some exemplary embodiments are described below with reference to the drawings. Elements having the same or similar elements or the same action may be denoted by the same reference numerals in this case.
1 is a schematic view of a valve according to an embodiment;
2 is a schematic view of a valve according to an embodiment; And
3 is a sectional view through a valve element according to an embodiment;

Fig. 1 schematically shows a cross-sectional view of a valve 100. Fig. The valve 100 includes a housing 101 and a valve seat body 105. The valve seat body 105 is coupled to the housing 101. The valve seat body 105 is arranged in the recess of the housing 101 in particular. The valve 100 is, for example, a pressure-limiting valve in a fuel injection system.

A valve seat body (105) surrounds the fluid inlet (106). Fluid inlet 106 is hydraulically coupled to, for example, a fuel line that guides high pressure or to a pressure accumulator. In particular, pressures in excess of 2000 bar appear on the high pressure side. The valve seat body 105 has a sealing sheet 107. The sealing sheet is arranged at one end of the fluid inlet 106. The valve seat body 105 has a guide surface 108 in a region facing away from the fluid inlet 106. The guide surface 108 is particularly cylindrical. The valve seat body 105 further surrounds the fluid chamber 111. The fluid chamber 111 is arranged between the sealing sheet 107 and the guide surface 108. In an embodiment, the valve seat body 105 surrounds the fluid line 110. Fluid line 110 is particularly a bore or a number of bores. The fluid line (110) is arranged between the guide surface (108) and the sealing sheet (107).

The housing 101 surrounds the fluid outlet 102 arranged downstream of the fluid line 110.

The valve 100 further comprises a valve element 103. Valve element 103 is a elongated valve pin or elongated valve needle, particularly extending along longitudinal axis 104.

The valve element 103 is coupled to the valve seat body 105. The valve element 103 is arranged in the region in the valve seat body 105. The valve element 103 is movable relative to the valve seat body 105 along the longitudinal axis 104. The movement of the valve element 103 relative to the valve seat body 105 is guided by the guide surface 108. With the valve closed, the valve element 103 comes into contact with the sealing sheet 107 at one end. At the opposite end, valve element 103 is coupled to actuator 113. The actuators are, in particular, electromagnetic actuators. This electromagnetic actuating member includes in particular a magnet coil 1132 and an armature 1131. The actuating body 113 is fixed to the housing 101 in particular. The actuating body 113 is designed to move the valve element 103 along the longitudinal axis 104 in a direction away from the sealing sheet 107. In particular, the armature 1131 can be deflected in the armature direction when the magnet coil 1132 is energized.

The valve seat body 105 is made of a material that is harder than the material forming the housing 101. In particular, the valve seat body 105 is made of a material that is harder than the housing 101. In particular, the valve seat body 105 has a greater hardness than the housing 101. In particular, the magnetic properties are not necessarily considered when selecting the material for the valve seat body 105. This material is basically chosen for low wear. The material of the housing 101 is selected for its magnetic properties when the electromagnetic actuator 113 is coupled to the housing 101. [

The guide surface 108 for the valve element 103 is part of the valve seat body 105 which is made of a relatively rigid material. The valve seat body 105 receives only low guide wear when guiding the valve element 103.

During operation, a high pressure fluid appears at the fluid inlet 106. When this pressure exceeds a predefined value or the actuating element is actuated, the valve element 103 is lifted from the sealing sheet 107. Thus, fluid flow from the fluid inlet 106 to the fluid outlet 102 is allowed. Whereby a fluid jet is created between the tip of the valve element 103 and the sealing sheet 107. The high pressure jet reaches the wall 112 of the fluid chamber 111. Since the fluid chamber 111 is formed in the valve seat body 105 composed of a rigid material, only low wear occurs as the jet reaches the wall 112. Fluid flows from fluid chamber 111 through fluid line 110 to fluid outlet 102.

In the valve 100, the sealing sheet 107 and the wall 112 are embodied as a single common part. Additional components to protect from fluid jets can be omitted. The guide surface 108 and the valve seat 107 are embodied as a single common part. Thus, a smaller manufacturing tolerance occurs. In particular, guide surface 108, seal sheet 107, and wall 112 are embodied as a single common part. Thereby, the valve 100 can be manufactured at a low cost and in a precise manner. Owing to the omission of additional components to be protected from high pressure, the valve becomes cheaper. The valve 100 receives only low wear in the fluid chamber 111 by the fluid jet. Furthermore, the valve seat body 105 is subject to low wear when guiding the valve element 103.

Figure 2 shows a valve 100 according to a further embodiment. The valve 100 according to FIG. 3 substantially corresponds to the embodiment described in conjunction with FIG. Unlike the embodiment of FIG. 1, the valve 100 according to the exemplary embodiment of FIG. 2 does not have a fluid line 110. Instead, a recess 109 or a number of recesses 109 are provided in the valve element 103.

3 shows a cross-sectional view of the valve element 103 of Fig. 2 in relation to the longitudinal axis 104. Fig. The recess 109 is formed laterally in the valve element 103 in the direction of the longitudinal axis 104. When the valve is open, the fluid is guided from the fluid chamber 111 through the recess 109 to the fluid outlet 102. Accordingly, the bore 110 can be eliminated from the valve seat body 105. The recess (109) extends beyond the guide surface (108) on the side facing away from the sealing sheet (107). A reliable fluid flow is realized through the recesses (109).

Claims (6)

As a valve,
A housing 101 surrounding the fluid outlet 102,
- a valve element (103) having a longitudinal axis (104), and
- a valve seat body (105) surrounding the fluid inlet (106) and having a sealing sheet (107) and coupled to the housing (101)
The valve 100 is closed when the valve element 103 supports the sealing sheet 107,
The valve element 103 is movable in the direction of the longitudinal axis 104 relative to the valve seat body 105 to permit fluid flow from the fluid inlet 106 to the fluid outlet 102,
The valve seat body 105 surrounds the guide surface 108 to which the valve element 103 is coupled to guide the movement of the valve element 103,
The valve seat body (105) is formed of a material that is harder than the housing (101). The valve of claim 1, wherein the coupling between the guide surface (108) and the valve element (103) is designed to introduce fluid between the guide surface (108) and the valve element (103). The valve element (103) according to any one of the preceding claims, wherein the valve element (103) comprises at least a section of the guide surface (108) when viewed along the longitudinal axis (109) for the flow of fluid to the valve (102). A valve seat according to any one of the preceding claims, wherein the valve seat body (105) is configured to be movable relative to the longitudinal axis (104) for fluid flow from the fluid inlet (106) And a fluid line (110) oriented laterally. The valve seat body (105) according to any one of claims 1 to 4, wherein the fluid jet is directed to the wall (112) when fluid flow is allowed from the fluid inlet (106) to the fluid outlet And encloses the fluid chamber (111) in the seal sheet (107) by the wall (112) to reach the fluid chamber (111). 6. The method according to any one of claims 1 to 5,
- an electromagnetic actuator (113) arranged in the housing (101) and coupled to the valve element (103) for moving the valve element (103) in the direction of the longitudinal axis (104).

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